Apparatus for removing an elongated structure implanted in biological tissue

ABSTRACT

Heart lead removal apparatus and method are disclosed for removing a heart lead from the wall of a heart through a blood vessel leading to the heart. The apparatus comprises a flexible stylet wire with an expandable wire coil attached to the distal end for securing the distal end of the stylet wire to the heat lead. A catch wire extends from the proximal end of the wire coil. The free end of the catch wire has a segment folded back on itself for engaging the coiled structure of the lead and expanding the wire coil when the stylet wire and wire coil are rotated in the passageway of the lead. The stylet wire is inserted in the longitudinal passageway of the coiled structure to the distal end of the heart lead. When inserted in the passageway, the stylet wire and wire coil are rotated in a direction to engage the catch wire with the coiled structure. The wire coil then expands engages the heart lead coiled structure, thereby securing the stylet wire to the heat lead. The heard lead is now secured for subsequent removal.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of application Ser. No. 07/347,217, filed May 3, 1989, entitled "Apparatus for Removing an Elongated Structure Implanted in Biological Tissue," which is a continuation-in-part of application Ser. No. 07/298,100, filed Jan. 17, 1989, entitled "Method and Apparatus for Removing an Implanted Pacemaker Lead," which is a continuation-in-part of application Ser. No. 07/269,771, filed Nov. 9, 1988, entitled "Method and Apparatus for Separating a Coiled Structure from Biological Tissue."

TECHNICAL FIELD

This invention relates to elongated structures, such as a catheter implanted in tissue or an electrical pacemaker lead implanted in the heart and, particularly, to apparatus for removing such elongated structures implanted in biological tissue.

BACKGROUND OF THE INVENTION

A heart pacemaker is generally implanted subcutaneously in the chest wall along with a coiled structure such as an electrical wire coil lead for conducting electrical signals such as stimulating and sensing signals between the pacemaker and the heart. The lead is surgically implanted through a vein leading to a cavity of the heart. A typical lead includes one or more helical wire coils having a hollow inner passageway that extends the entire length of the wire coil. The coiled structures are positioned in the lead either coaxially or laterally. The wire coils are surrounded by an insulating material such as a flexible tube, sheath, or coating comprising, for example, silicon or polyurethane for insulating the wire coils from body fluids as well as each other. However, one problem is that, over time, fibrotic tissue commonly encapsulates the pacemaker lead especially in areas where there is low velocity blood flow. When small diameter veins through which the lead passes become occluded with fibrotic tissue, separating the lead from the vein is difficult and causes severe damage or destruction of the vein. Furthermore, the separation is usually not possible without restricting or containing the movement of the pacemaker lead.

In most cases, the useful life of a pacemaker lead lasts for many years. However, should the pacemaker lead become inoperative or should another heart lead be desired, the existing pacemaker lead is typically left in place, and a new pacemaker lead is implanted. One problem with leaving an implanted lead in place, particularly in the heart, is that the lead actually restricts the operation of the various heart valves through which the lead passes. If several leads passing through a heart valve are left in place, the operation of the heart valve and the efficacy of the heart is significantly impaired.

Another problem associated with leaving a pacemaker lead in place, particularly in blood vessels, is that an infection may develop in or around the lead, thereby requiring surgical removal. Surgical removal of the lead from the heart often involves open heart surgery with accompanying complications, risks, and significant cost.

One method for transvenous removal of a pacemaker lead involves a prior art heart lead removal tool that utilizes a hollow, rigid tube and a beveled rod tip for engaging and deforming the coiled structure of the heart lead. However, when the lead cannot be removed because of some complication, a serious problem is that the tip of the tool is locked in place and cannot be removed from the lead. As a result, the tool and lead must be surgically removed. Furthermore, the rigid tube of the tool can easily puncture a blood vessel or, even worse, a heart cavity wall.

Another method is to transvenously extract the lead manually without the aid of a tool. Such method is possible only when the lead has not been encapsulated in or restricted by a blood vessel. Even then, this method has a number of problems. First, when the polyurethane or silicon insulation surrounding the wire coil is damaged, the insulation can sever and cause the coiled structure of the lead to unwind and possibly to damage the heart and surrounding blood vessels. Secondly, when both the coiled structure and insulation are severed in the heart or a blood vessel, surgical removal is required. Thirdly, most pacemaker leads typically include tines or a corkscrew at the tip or a conically shaped tip for securing the distal end of the pacemaker lead to a heart cavity wall. For fibrotic tissue that has encapsulated the tip, unaided manual removal of the heart lead from the heart cavity wall may cause an inward extension or inversion of the wall, or even worse, permanent damage to the heart such as tearing a hole in the heart cavity wall.

SUMMARY OF THE INVENTION

The foregoing problems are solved and a technical advance is achieved with illustrative apparatus for removing an elongated structure such as a catheter or an electrical pacemaker lead implanted in biological tissue such as a blood vessel or a heart cavity wall. The illustrative apparatus includes a control unit having a longitudinal passageway such as a flexible tube that is insertable in the longitudinal passageway of the catheter or the wire coil of the pacemaker lead for controlling movement of the elongated structure. Positioned about the distal end of the control unit is an expandable unit that is operable to a position for securing the control unit to the elongated structure. The control unit passageway is used for operating the expandable unit.

In a first embodiment, the control unit is a flexible tube with one or more side ports or apertures for passing a fluid therethrough for operating the expandable unit. In this embodiment, the expandable unit is a balloon attached about the distal end of the tube with the side ports leading from the passageway for inflating or expanding the balloon to an expanded position for securing the control unit to the elongated structure.

In a second embodiment, the control unit again includes a flexible tube. The expandable unit includes a number of twisted radial projections each having a free end that is formed from radial strips cut in the distal end of the tube. The strips are twisted at the free end and pushed into the passageway of the tube. The apparatus further comprises an actuator such as a rod that is inserted into the passageway of the tube to engage and expand the free end of the projections into the wire coil of the pacemaker lead, thereby securing the control tube to the wire coil.

In a third embodiment, a plurality of expandable strips are longitudinally formed in the distal end of the control tube. The actuating rod of the apparatus is inserted in the tube passageway and attached at the distal end of the tube. When the apparatus is inserted in the passageway of the elongated structure, the actuator rod is pulled in a direction out of the tube while operating the deformable strips into an expanded position engaging the wall of the structure passageway for securing the control tube to the elongated structure.

In a fourth embodiment, a number of barbs or a helical ridge is formed at the end of the control tube. The expandable distal end of the control tube is partially collapsed or formed such that the barbs or ridge when expanded by an actuator rod extend beyond the nominal diameter of the tube. The actuator rod is extended through the tube passageway to expand the distal end of the tube and cause the barbs or ridge to engage the structure and secure the control tube thereto.

In a fifth embodiment, the apparatus also includes a hollow control tube having a longitudinal passageway therein. An expandable slotted sleeve is positioned at the distal end of the control tube. An actuator rod is inserted through the slotted sleeve and control tube. The distal end of the rod is enlarged to engage and expand the slotted sleeve against the distal end of the control tube. When inserted in the passageway of the elongated structure, the actuator rod is pulled in a direction out of the control tube passageway to force the enlarged distal end of the rod into the passageway of the slotted sleeve and expand the slotted sleeve into the wall of the elongated structure. As a result, the control tube is secured to the elongated structure for controlling the movement thereof.

In sixth and seventh illustrative embodiments similar in function to the fifth embodiment, an expandable sleeve comprising a pliable material is positioned between the distal ends of the control tube and actuating rod. In the sixth embodiment, the pliable material sleeve is compressed between the distal ends of the control tube and actuator rod to expand and engage the passageway walls of the elongated structure. In the seventh embodiment, the pliable material sleeve is already in an expanded position to engage the passageway walls of the elongated structure. To insert this expanded pliable material sleeve into the passageway of the elongated structure, the actuator rod is pushed into the passageway of the control tube to longitudinally stretch the pliable material sleeve. As a result, the outside diameter of the sleeve is compressed to allow the apparatus to be inserted into the passageway of the elongated structure. When inserted, the actuator rod is released allowing the sleeve to radially expand and engage the wire coil or passageway walls of the elongated structure.

The invention is further directed to removal apparatus having a guide that is insertable into the passageway of the elongated structure for guiding the control unit in the passageway. In those instances where the passageway of the elongated structure has become blocked or occluded, the apparatus advantageously includes this guide for breaking through the occlusion. Furthermore, various diameter guides are inserted into the structure passageway for determining the minimum passageway diameter of the structure when the structure has in some way been deformed or damaged. Illustratively, the guide includes a stylet wire that is first inserted into the passageway of the elongated structure. When the stylet guide has been inserted, the control tube is inserted over the proximal end of the stylet wire and inserted into the passageway of the structure. In one embodiment, the expandable unit of the apparatus includes a wire coil positioned around and attached at its distal end to the control tube. When inserted, the control tube is rotated to expand the wire coil and secure the control tube to the elongated structure.

In another embodiment, the expandable unit includes a balloon attached about the distal end of the control tube. The control tube includes a second passageway that leads to the balloon for inflating the balloon to secure the control tube to the passageway wall of the elongated structure.

The invention is also directed to a removal apparatus having a rotatable unit for securing the control unit to the elongated structure. In one illustrative embodiment, the removal apparatus includes a control tube insertable into the passageway of the elongated structure for controlling the movement thereof. Positioned about the distal end of the control tube is a rotatable unit such as a cylindrical rod that is rotatable to a position off-centered from the tube for securing the control tube to the elongated structure. The apparatus also includes an actuator rod extending through the control tube and attached off-centered to the cylindrical rod for rotating the rod into the off-centered position securing the control tube to the structure.

The invention is still further directed to removal apparatus having a control tube that is insertable into the passageway of the elongated structure and has an extended projection at the distal end thereof for securing the tube to the structure. Also included is a stylet that is insertable into the passageway of the tube for operating the extended projection to a retracted position for insertion or removal of the control tube from the passageway of the elongated structure.

The invention also includes apparatus for separating the elongated structure from tissue that is restricting the movement and, consequently, the removal of the elongated structure. In one illustrative embodiment, the separating apparatus includes a tube having a first passageway for receiving the elongated structure. Positioned about the distal end of the tube is a balloon that is inflatable for separating restricting tissue from a length of the elongated structure. A second passageway extending along the tube and to the balloon is included for inflating the balloon.

In another embodiment, the separating apparatus includes a first tube having a passageway for receiving the elongated structure and a distal end for separating the structure from the restricting tissue as the elongated structure is received into the passageway. Also included is a second tube having a passageway for receiving the elongated structure and the first tube for separating the restricting tissue from either the first tube or the elongated structure. Advantageously, at least one of the two tubes comprises a polypropylene material, which is much less susceptible to kinking than TEFLON material. In operation, two tubes are alternately moved along the elongated structure to provide tissue separation. The second tube advantageously adding strength to the removal apparatus for separating the restricting tissue. A control mechanism having a passageway for passing the proximal end of the elongated structure therethrough is also attached to the proximal end of the first tube for controlling movement of the first tube in either a rotational or longitudinal direction about the elongated structure. To facilitate visualization of the separating apparatus in biological tissue such as a blood vessel, at least one of the two tubes includes a radioopaque material such as bismuth.

The invention also includes apparatus for separating the distal end of an elongated structure such as a pacemaker lead from heart tissue affixed thereto. In one illustrative embodiment, the separating apparatus includes first and second concentric tubes each having a passageway for receiving the structure to the distal end thereof. An elongated member such as stainless steel wire or suture material is extendable between the distal ends for cutting the distal end of the structure from the tissue. When the tubes are positioned at the distal end of the coiled structure, the tubes are rotated in opposite directions to wipe the wire or suture material across the distal ends of the tubes and structure, thereby cutting the distal end of the structure from the affixed tissue. At least one of the tubes also has a second passageway or channel for controlling the amount and the tension of the elongated means at the distal ends thereof.

In a second illustrative embodiment, the separating apparatus includes a tube having a passageway for receiving the lead. The distal end of the tube is extendable to the distal end of the pacemaker lead. Included at the distal end of the tube is a plurality of slots for receiving the tines of the pacemaker lead. When the tines have been positioned in one or more of the slots, the tube is rotated for separating the tines and distal end of the lead from the encapsulating tissue.

The invention is further directed to apparatus for expanding the proximal end of a severed coiled structure of a pacemaker lead. Advantageously, this expands the wire coil structure of a pacemaker lead to insert a sizing stylet or gauge to accurately determine the diameter of the wire coil of the pacemaker lead. When the connector end is severed from the proximal end of the pacemaker lead, the severing operation deforms the wire coil and provides a false indication of the true diameter of the passageway extending to the distal end of the lead. The expanding apparatus includes a tapered rod having distal end with a first diameter that is easily insertable into a passageway of the coiled structure of the pacemaker lead. The rod has a tapered longitudinal portion extending from the distal end to a proximal end having a second diameter greater than the first diameter. The tapered portion engages and expands the proximal end of the severed coiled structure when inserted therein. The apparatus also includes a control mechanism attached to the rod for controlling movement of the rod in the passageway of the coiled structure.

Lastly, the invention includes apparatus for removing an elongated coiled structure implanted in biological tissue such as the wire coil of a pacemaker lead implanted in the heart through a blood vessel leading thereto. The apparatus includes a stylet wire that is insertable into a longitudinal passageway of the coiled structure for controlling movement of the structure. A wire coil is attached at its distal end to the distal end of the stylet wire and is expandable for securing the stylet wire to the coiled structure. The proximal end of the wire coil is extended from the wire coil and stylet wire for engaging the coiled structure and for controlling expansion of the wire coil.

In another illustrative embodiment of this removal apparatus, the proximal end of the wire coil forms a catch wire having a folded-back segment for engaging the coiled structure of the pacemaker lead. The folded-back segment is illustratively attached to the catch wire using silver solder. This folded-back segment of the catch wire advantageously engages the coiled structure of the lead with only a few turns of the stylet wire and operation of the wire coil rather than 10-20 as previously required. With rapid engagement, the stylet wire and wire coil maintain a relatively fixed longitudinal position in the passageway. Previously, the relatively large number of turns required to engage the wire coil with the coiled structure allowed the removal apparatus to be withdrawn or pulled out of the passageway one or more inches. Engagement of the wire coil and coiled structure with only several turns of the stylet wire prevents the stylet wire from partially pulling out of the passageway and possibly allowing the distal end of the pacemaker lead to break off and remain in the heart cavity wall. The length of the catch wire is preferably one quarter of an inch with the folded-back segment being a sixteenth of an inch in length to advantageously engage the coiled structure with the least number of rotations of the stylet wire.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1 depicts a partial cross-sectional view of a heart having an electrical pacemaker lead implanted therein;

FIG. 2 depicts a partial cross-sectional view of a prior art tool inserted in the passageway of a heart lead for removing the lead;

FIG. 3 illustrates sections of the apparatus of the present invention for separating a length of a heart lead restricted in a blood vessel and for separating the tip of the heart lead from a heart cavity wall;

FIG. 4 illustrates the leading edge of the separator tube of the apparatus of FIG. 3 for separating the heart lead from a blood vessel as partially shown in FIG. 1;

FIG. 5 depicts a lockable mechanism for grasping the proximal end of the pacemaker lead of FIG. 1;

FIG. 6 depicts an enlarged view of the lockable mechanism of FIG. 5 along the lines 6--6;

FIG. 7 depicts another embodiment of the lead removal apparatus of this invention;

FIG. 8 depicts the lead removal apparatus of FIG. 7 with the stylet wire secured to the pacemaker lead;

FIG. 9 depicts a device for expanding the proximal end of the coiled structure of FIG. 3;

FIGS. 10-21 depict alternative embodiments of the removal apparatus of FIG. 3;

FIGS. 22 and 27 depict alternative embodiments of the apparatus for separating encapsulating tissue from a pacemaker lead of FIG. 3;

FIG. 23 depicts an alternative embodiment of the apparatus for removing an elongated coiled structure implanted in biological tissue of FIG. 3;

FIGS. 24-26 depict illustrative apparatus for separating the distal end of an elongated structure from tissue affixed thereto; and

FIGS. 28 and 29 depict another alternative embodiment of the removal apparatus of FIG. 3.

DETAILED DESCRIPTION

Depicted in FIG. 1 is a partial cross-sectional view of heart 215 connected to a plurality of arteries and veins such as the right subclavian vein 216 through which an electrical heart pacemaker lead 204 has been implanted. The lead passes internally through the right subclavian vein 216, the superior vena cava 208 and into the right ventricle 217 of the heart. The distal end of the lead includes an electrode 220 for electrically stimulating the heart and is secured to the apex of the right ventricle with a plurality of tines 207, which in time become securely attached to the ventricle wall by endothelial tissue forming around the heart lead tip. Some ventricles are relatively smooth on the inside, but most have trabeculae amongst which the tines are secured into position. External to the right subclavian vein, the proximal end 221 of the lead is grasped by a lockable mechanism 222, which will be described hereinafter.

Depicted in FIG. 2 is a partial cross-sectional view of a prior art tool 100 for removing a heart lead 111 which has been secured to a heart cavity wall 113 via trabeculae and/or fibrotic tissue 104. The lead includes an electrical coiled structure 101 and insulating material 102 that is formed essentially into a tube for covering the outer surface of the coiled structure and for preventing fluids from entering the coiled structure. At the distal end of the heart lead are tines 103, that are formed from the insulating material, for securing the heart lead tip including electrode 109 to the heart cavity wall. Tool 100 includes a hollow rigid tube 105 and beveled rod 106 for inserting in the longitudinal passageway 110 of the heart lead coiled structure. In the passageway of hollow tube 105 is an actuating wire 107 connected to beveled rod 106. The trailing edge of the beveled rod and the leading edge of the hollow tube are inclined at an angle for moving the beveled rod across the distal end of the hollow tube when the actuating wire is pulled. When moved, the beveled rod engages and deforms the heart lead coiled structure as shown. The deformed coiled structure locks the hollow tube and beveled rod in place for limiting movement of the heart lead. However, once secured, beveled rod 106 may not be extracted from passageway 110 of the coiled structure since the deformed coiled structure prevents the beveled rod and actuating wire from traversing the passageway. The prior art tool also includes a hollow dilator 108 for sliding over the heart lead coil and separating the heart lead from the blood vessel. A hollow explanator 112 passes over the dilator and is rotated back and forth to explant the tip of the heart lead from the securing tissue and heart wall.

Depicted in FIG. 3 is a flexible stylet wire 200 of the present lead removal apparatus invention that is insertable in the longitudinal passageway 210 of a heart lead coiled structure 211 for controlling and, in particular, limiting the movement of heart lead 204 including coiled structure 211. Heart lead 204 also includes insulating material 201, such as silicone or polyurethane, formed into a hollow tube that surrounds the coiled structure and prevents fluids from making contact with the coiled structure. Attached to the distal end of the flexible stylet wire is an expandable wire coil 205 consisting of approximately 25 turns of wire with spacing between the turns. Five to seven wraps of the wire coil are attached to the distal end of the stylet wire using, for example, solder 206. The remaining wraps of the wire coil remain free for engaging the coiled structure when the proximal end of the stylet wire is rotated in a direction to unwind and expand the turns of the wire coil and engage the coiled structure of the heart lead. A bead 214 of high temperature silver solder is applied to the distal end of the stylet wire to prevent the distal end thereof from pulling through the wire coil during separation and removal of the heart lead. Positioned about the proximal end of the stylet wire is control mechanism 202 for rotating the stylet wire in either a clockwise or counterclockwise direction or for moving the wire in a longitudinal direction into or out of the passageway. In this embodiment, control mechanism 202 is a loop of wire formed from the stylet wire of which the physician may grasp or insert his finger. The loop may also be fashioned for attachment to another control mechanism for moving the stylet wire. Other control mechanisms such as a slidable chuck may be positioned at the proximal end of the stylet wire to facilitate movement of the stylet wire. The formed loop 202 is covered with TEFLON material tubing 203 or other suitable material for facilitating the easy movement of the stylet wire. The looped end is also compressible for inserting through a separator tube 212.

The choice of the stylet wire and wire coil varies with the internal diameter of the coiled structure which varies from 0.016" to about 0.028" for most heart leads. The diameter of the stylet wire would then range from 0.009" to 0.015", with the coil wire ranging in diameter from 0.003" to 0.006". The use of stainless steel wire is preferable. The stylet wire should be hardened wire, but ductable wire may be used for the coil wire.

Before the stylet wire is inserted into passageway 210 of the lead, the inside diameter of the coiled structure and the outside diameter of the insulating material are determined. First, lockable mechanism 222 is first applied to the proximal end 221 of the lead between opposing semicircular jaws 223 and 224. The details of mechanism 222 are depicted in FIGS. 5 and 6. Semicylindrical pliable material 225 and 226, such as latex, are affixed with medical grade adhesive to the opposing faces of the jaws. Semicylindrical pliable material 225 includes semicylindrical channels 227 and 229 having different radii, and pliable material 226 includes semicylindrical channels 228 and 230 with radii corresponding to channels 227 and 229, respectively. When jaws 223 and 224 are in a closed position, the opposing surfaces 231 and 232 of respective pliable material 225 and 226 are in contact with opposing channels 227 and 228 forming one hollow cylindrical passageway with a first diameter and opposing channels 229 and 230 forming a second hollow cylindrical passageway with a second larger diameter. The two different size diameter passageways in the pliable material accommodate a number of different size diameter pacemaker leads and are designed to grasp and apply pressure to insulating material 201 in a uniform manner.

When proximal end 221 of lead 204 is inserted and grasped in the hollow passageway formed by channels 229 and 230, insulating material 201 is compressed onto coiled structure 211, thus limiting the movement of the structure within the insulating material. When the physician cuts the lead for access to the passageway of the lead, the compressed insulating material prevents the coiled structure from retracting into the passageway of the lead.

Pivotly interconnected elongated members 233 and 234 are connected to respective opposing jaws 223 and 224 to operate the jaws between open and closed positions. The proximal ends 235 and 236 of the members are curved as shown in FIG. 5 to oppose each other and have a respective plurality of teeth 237 and 238 that interlock to form a locking mechanism. The locking mechanism is actuated by squeezing the proximal ends of the members and opposingly positioning the teeth thereon. When so positioned, the teeth of mechanism 222 interlock and maintain opposing jaws 223 and 224 in a closed position.

After the lockable mechanism is applied to the proximal end of the pacemaker lead, a pair of well-known wire cutters or snips sever the electrical connector (not shown) from the proximal end 222 of pacemaker lead 204. As a result of such severance, coiled structure 211 of the pacemaker lead is commonly deformed, thereby presenting a false indication of the actual diameter of longitudinal passageway 210. As a consequence, the physician inserts expansion device 901 into the proximal end of hollow passageway 210 to expand coiled structure 211.

Depicted in FIG. 9 is expansion device 901 for expanding the deformed proximal end of coiled structure 211. The expansion device includes a tapered rod 902 having a distal end 903 with a diameter that is easily insertable into the passageway of the deformed coiled structure. Tapered rod 902 includes a tapered longitudinal portion 904 that gradually increases in diameter to proximal end 905 that has a diameter significantly greater than the diameter of the distal end. Control handle 906 is connected to the proximal end of the tapered rod. The physician grasps the control handle to insert the tapered rod into the longitudinal passageway and to expand the deformed proximal end of the coiled structure.

With lockable mechanism 222 in a closed position and the proximal end of the coiled structure expanded, the physician selects a wire guide 239, as shown in FIG. 3, having a diameter less the diameter of the lead passageway. The physician determines the passageway by inserting the wire guide therein and sensing for any blockages. The guide includes a control mechanism such as a knurled cylindrical chuck 240 positionable about the proximal end thereof. The physician grasps the knob to extend the guide into the lead passageway and to rotate the guide back and forth to clear or break through any blockages caused by tissue or occluding material. The guide is also used to determine or size the inside diameter of a second coiled structure that may be coaxially positioned inside coiled structure 211. When utilized as a control mechanism for stylet wire 200, the chuck may also include appendages 260 for rotating and counting the number of times the stylet wire is rotated. Having determined the lead passageway with the wire guide, several other guides similar to guide 239 are individually inserted in the passageway to determine the actual inside diameter at the proximal end. Guide 239 is also utilized to determine if coiled structure 211 has been deformed or damaged and to determine the smallest diameter of the coiled structure and passageway.

As shown in FIG. 3, stylet wire 200 is inserted into longitudinal passageway 210 of coiled structure 211. The diameter of the coil wire and stylet wire have been selected to form a combined overall diameter which approximates the diameter of the longitudinal passageway of the heart lead coiled structure within a predetermined tolerance such as one or two thousandths of an inch. Stylet wire 200 is then fed through the entire length of the passageway to the distal end of the coiled structure which is secured to the wall of heart cavity tissue 213 via tines 207. When fully inserted into the heart lead, the distal ends of the stylet wire and coiled structure should be in close proximity. It is not necessary, but probably more advantageous, that the stylet wire be attached to the distal end of the heart lead. For separating the heart lead from adjacent tissue, the stylet wire may be secured anywhere along the passageway of the coiled structure past the restricting tissue. To secure the stylet wire to coiled structure 211, looped end 202 of the stylet wire is operated in a circular direction to unwind and expand wire coil 205. As a result, the turns of the wire coil and coiled structure engage and intermesh, thereby firmly securing the stylet wire to the heart lead. This prevents any extension or stretching of the heart lead and also controls and limits the movement of the lead when separator tube 212 is moved along the length of coiled structure 211 and insulating material 201 of the heart lead.

Depicted in FIG. 23 is illustrative removal apparatus 2301, which is an alternative embodiment of stylet wire 200. Removal apparatus 2301 is insertable into the longitudinal passageway of an elongated structure such as a pacemaker lead. The removal apparatus includes a stylet wire 2302 with a conically-shaped silver solder tip 2303 that is positioned at the distal end thereof. Closely wrapped wire coil 2304, similar to wire coil 205, is attached at the distal end of the stylet wire using silver solder 2305 as previously described. The proximal end of the wire coil is pulled to unwrap several turns of wire coil 2304. A catch wire 2306 is formed from the proximal end of the wire coil to extend in a radial direction from the wire coil and stylet wire. Catch wire 2306 catches on or engages the coiled structure of the pacemaker lead to engage wire coil 2304 with the coiled structure of the pacemaker lead. In addition, the wire coil may be rotated in the opposite direction to release the stylet wire from the coiled structure if desired.

Depicted in FIG. 28 is illustrative removal apparatus 2801, which is another alternative embodiment of the removal apparatus depicted in FIG. 3. Removal apparatus 2801 is insertable into the longitudinal passageway of an elongated structure such as passageway 210 in pacemaker lead 204 of FIG. 3. The removal apparatus includes a stylet wire 2802 and a wire coil having closely-spaced turns 2804 and open-spaced turns 2809. At the distal end 2803 of the removal apparatus, closely-spaced turns 2804 are attached to the distal end of stylet wire 2802 using sliver solder 2805. The distal end 2803 is tapered or conically shaped for easy insertion into the pacemaker lead passageway. The distal end is tapered or shaped using any of a number of well-known techniques such as sanding, grinding, buffing, or a combination thereof. Several turns at the proximal end of the wire coil are unwrapped to form a catch wire 2806 that extends radially from the wire coil and stylet wire. Catch wire 2806 catches on or engages the coiled structure of the pacemaker lead when inserted in the passageway thereof for engaging open-spaced turns 2809 with the coiled structure of the pacemaker lead. With control mechanism 202, the stylet wire is typically rotated in a counter-clockwise direction for operating the wire coil and engaging the open-spaced turns of the wire coil with the coiled structure of the pacemaker lead. To more readily engage the coiled structure, the proximal end 2807 of the catch wire is folded back on itself and attached thereto with silver solder 2808. A side view of the proximal end of catch wire 2806 taken along the line 29--29 is depicted in FIG. 29. The proximal end 2807 is folded back and attached to catch wire 2806 so as not to extend beyond the thickness of the wire as shown in FIG. 28. This is to prevent the catch wire from engaging the coiled structure of the pacemaker lead or binding between the stylet wire and coiled structure when the removal apparatus is being inserted in the passageway of the coiled structure. Experiments in the laboratory and in actual pacemaker lead removals indicate that the length of catch wire 2806 should be preferably one-quarter of an inch in length. The folded-back segment end 2807 should preferably be one-sixteenth of an inch in length. As a result, only a few counterclockwise turns of the stylet wire in laboratory tests were found necessary to engage the coiled structure of the pacemaker lead. Previously, ten to twenty turns were required to engage the coiled structure when the catch wire did not include the folded-back proximal end.

Depicted in FIGS. 10-21 are alternative embodiments of illustrative apparatus for removing the elongated structure implanted in biological tissue. All of these alternative embodiments are for controlling the movement of an elongated structure. The removal apparatus in each of these alternative embodiments includes a control unit that is insertable into the longitudinal passageway of the elongated structure, such as a pacemaker lead, and securable to the structure for controlling the movement thereof. The apparatus also includes an expandable unit positioned about the distal end of the control unit and operable to an expanded position for securing the control unit to the elongated structure. However, the control unit in each of these alternative embodiments commonly, but not in all cases, includes a longitudinal passageway for operating the expandable unit to the expanded position for securing the control unit to the elongated structure.

Depicted in FIG. 10 is a first alternative embodiment of illustrative removal apparatus 1001 for removing implanted pacemaker lead 204. The control unit of this removal apparatus includes a flexible tube 1002 having a passageway 1003 formed longitudinally therein. Expandable balloon 1004 is positioned and attached about the distal end of the control tube. The distal end of the control tube is also recessed to attach to the balloon in a well-known manner at the ends of radial recess 1005. The recess also provides a volume in which the collapsed balloon is stored. The recess also includes one or more side ports 1006 leading from passageway 1003 to the balloon. A source of fluid such as compressed air or liquid is passed through the passageway and into the balloon to inflate the balloon to an expanded position as indicated by expanded balloon 1007 positioned at the distal end of the lead.

Depicted in FIG. 11 is a second alternative embodiment of illustrative removal apparatus 1100. In this second alternative embodiment, the control unit also includes a control tube 1101 for insertion into passageway 210 of coiled structure 211. The expandable unit comprises a plurality of radial projections 1102 and 1103 that have a free end are radially formed in the distal end of the control tube. The free end of the radial projection is twisted and bent in an inward direction into passageway 1104 of the control tube. As formed, these projections allow a control tube to be easily inserted into passageway 210 of the coiled structure. When control tube 1101 is positioned at the distal end of the coiled structure, actuator rod 1105 is inserted in passageway 1104 of the control tube. When inserted, the actuator rod engages the radial projections and forces them into an expanded position extending radially from the surface of the control tube into the coiled structure of the pacemaker lead. When in the expanded position, these radial projections secure the control tube to the coiled structure, thereby controlling movement of the coiled structure during removal from the tissue.

Depicted in FIG. 12 is a third alternative embodiment of illustrative removal apparatus 1201 utilizing an actuator rod 1202. The removal apparatus includes a control tube 1203 that is extendable into the longitudinal passageway of a pacemaker lead. The expandable unit of the apparatus comprises a plurality of longitudinal strips 1204 formed at the distal end of the control tube. Actuator rod 1202 is inserted in the passageway of the control tube and attached to the distal end 1205 thereof. When the control tube is inserted in the longitudinal passageway of the pacemaker lead, the actuator rod 1202 is pulled in a longitudinal direction out of passageway 1206 of the control tube as shown by arrow 1207. Typically, the physician will maintain the relative position of the proximal end of control tube 1203 while the actuator rod is pulled in the outward direction. As a result, distal end 1205 is forced toward the proximal end of the control tube, as shown by arrow 1208, thereby deforming longitudinal strips 1204 in an outward direction as indicated by arrows 1209. The expanding strips engage the coiled structure and secure the control tube to the coiled structure of the pacemaker lead.

Depicted in FIG. 13 is a fourth embodiment of illustrative removal apparatus 1301 inserted in the longitudinal passageway 210 of coiled structure 211. Removal apparatus 1301 includes a control tube 1302 having a distal end with a spiral or helical ridge 1303 formed therein. Alternatively, a number of barbs are formed in the contoured distal end of control tube 1302. The distal end includes a plurality of slits 1307 or an opening thereat for expanding the ridge or barbs into the coiled structure. Actuator rod 1304 is inserted into passageway 1305 to engage the distal end. When engaged, actuator rod expands the ridge or barbs in a radial direction, as shown by arrows 1308, to engage the coiled structure of the pacemaker lead. As a result, the expanded ridge or barbs secure the control tube to the coiled structure for controlling the movement thereof.

Depicted in FIG. 14 is a fifth embodiment of illustrative removal apparatus 1401 inserted in longitudinal passageway 210 of coiled structure 211. The removal apparatus includes control tube 1402 and actuator rod 1403 extending through hollow passagewaY 1404 of the control tube. The apparatus also includes a diagonally-slotted sleeve 1405 that is positioned between the distal ends of the control tube and actuator rod. The actuator rod also extends through hollow passageway 1406 of the sleeve. Attached to the distal end of the actuator rod is beveled tip 1407 having an outside diameter approximating the diameter of the control tube and the nominal diameter of the slotted sleeve. Similarly, the distal end of the control tube is beveled to engage and expand the slotted sleeve. To expand the slotted sleeve, the actuator rod is pulled, as indicated by arrow 1408, to engage the sleeve against the beveled edges of the control tube and the rod. As a result, the sleeve is expanded to a position for engaging coiled structure 211 and securing the control tube thereto. The slotted sleeve expands in a radial direction as indicated by arrows 1409.

Sixth and seventh alternative embodiments of illustrative removal apparatus 1501 and 1601 are depicted in FIGS. 15 and 16, respectively. In FIG. 15, removal apparatus 1501 includes a control tube 1502 and an actuator rod 1503 extending through longitudinal passageway 1504 of the control tube. The distal end of the actuator rod includes enlarged tip 1505 having a diameter approximating the diameter of the control tube. The device also includes expandable sleeve 1506 comprising a pliable material such as synthetic rubber and the like which expands in a radial direction when compressed between the distal end of the control tube and the enlarged tip of the actuator rod. In the relaxed state, the outside diameter of the pliable material approximates that of the control tube and enlarged tip of the actuator rod for insertion into longitudinal passageway 210 of the coiled structure. When inserted into passageway 210, the enlarged tip and distal end of the control tube compress and radially expand the pliable material in an outward direction toward the coiled structure as indicated by arrows 1507. The actuator rod is pulled through the passageway of the control tube as indicated by arrow 1508. As a result, pliable material 1506 is longitudinally compressed as shown by arrows 1509 and 1510. However, pliable material 1506 also expands in a radial direction and engages the coiled structure, thereby securing the control tube thereto.

Similarly, illustrative removal apparatus 1601 depicted in FIG. 16 includes control tube 1602 having longitudinal passageway 1610, actuator rod 1603 having an enlarged distal tip 1604, and pliable material 1605 attached to the distal end of control tube 1602 and enlarged actuator rod tip 1604. However, unlike pliable material 1506, pliable material 1605 in a relaxed condition has an outside diameter greater than the diameter of longitudinal passageway 210. Therefore, to insert the removal apparatus in the passageway, actuator rod is forced into passageway 1610 as indicated by arrow 1606, thereby stretching pliable material 1605 as indicated by arrows 1607 and 1608. As a result, the outside diameter of the pliable material decreases as indicated by arrows 1609 for insertion into the passageway of the elongated structure. When inserted, the actuator rod is released, and the pliable material attempts to return to its relaxed state. As a result, the pliable material engages the coiled structure and secures the device to the pacemaker lead.

Depicted in FIGS. 17 and 18 are alternative embodiments of illustrative removal devices 1701 and 1801 that include a wire guide for inserting into the longitudinal passageway of the elongated structure. In FIG. 17, removal apparatus 1701 includes wire guide 1702 that is inserted into passageway 210 of coiled structure 211 to clear any blockage formed therein and establish a guide for control tube 1703. When the guide wire is fully inserted, the control tube is inserted over the guide wire and then into passageway 210 of the structure. The control tube also has a longitudinal passageway 1706 for receiving the wire guide therein. Also included is wire coil 1704 that is positioned and attached at the distal ends thereof using, for example, silver solder 1705. As previously described with respect to stylet wire 200, control tube 1703 is rotated in a direction opposite that of coiled structure 211 for engaging and expanding wire coil 1704, thereby securing the control tube to the coiled structure.

As depicted in FIG. 18, removal apparatus 1801 includes wire guide 1802 that is inserted into the passageway of the elongated structure. Control tube 1803 includes two longitudinal passageways 1804 and 1805. Passageway 1804 receives the wire guide as the control tube is inserted into the passageway of the elongated structure. Positioned at the distal end of the control tube is inflatable balloon 1806 with passageway 1805 leading thereto through sideport or aperture 1807. To secure the control tube to the elongated structure, a fluid is passed through passageway 1805 to inflate the balloon to an expanded position.

Several other alternative embodiments of illustrative removal apparatus are depicted in FIGS. 19-21. Depicted in FIG. 19 is removal apparatus 1901 that includes control tube 1902 and cylinder 1903. The tube includes longitudinal passageway 1904. Cylinder 1903 is positioned about the distal end of the control tube and rotated to a position off-center of the tube for securing the control tube to the elongated structure. The removal apparatus includes an actuator rod 1904 extending through the control tube and attached to the rotatable cylinder. The rod rotates the cylinder to an off-centered position for securing the control tube to the elongated structure such as the coiled structure of a pacemaker lead. Actuator rod 1904 extends between the rotatable cylinder and control mechanism 1905 that is positioned at the proximal end of the control tube. Control mechanism 1905 is rotatable between two positions for rotating the actuator rod and the cylinder between expanded and retracted positions. The actuator rod is attached to the cylinder at an off-centered position to permit rotation of the cylinder and engagement of the elongated structure. Plug 1907 is inserted at the distal end of the tube to maintain the off-centered position of the rod in the passageway.

Depicted in FIG. 20 is illustrative removal apparatus 2001 including a control tube 2002 that has a longitudinal projection 2003 extending at the distal end thereof for securing the control tube to the coiled structure of a pacemaker lead. This arrangement is sometimes referred to as a flea-clip arrangement. Depicted in FIG. 21 is a sectioned view, taken along the lines 21--21 in FIG. 20, of the apparatus in passageway 210 of coiled structure 211. As shown, a stylet wire or rod 2004 is inserted into passageway 2005 of control tube 2002 to engage and retract the extended projections into the wall of the control tube. When the apparatus is inserted to the distal end of the coiled structure, the stylet wire or rod is removed from the passageway of the control tube. As a result, the springlike projections extend into the coiled structure of the lead, thereby securing the control tube to the coiled structure for controlling the movement thereof. To remove the control tube, the rod is inserted into the control tube passageway as shown by arrow 2101 to again engage the projections. When the rod engages the projections extending into the passageway, the inward extending projections move into the wall in a direction as shown by arrows 2103, whereas the outward extending projections move into the will in a direction as shown by arrows 2102.

The reader's attention is again referred to the preferred embodiment depicted in FIG. 3. After the stylet wire is secured to the lead and prior to inserting separator tube 212 over the stylet wire and lead, a tie 241 of, for example, nylon cord or suture material is wrapped around proximal end 221 of the lead to secure insulating material 201 to coiled structure 211. The tie controls or limits the movement of the coiled structure within the insulating material. With the insulating material secured to the coiled structure at the proximal end, removal force is applied not only to the coiled structure, but also to the insulating material of the lead as well. This maintains the integrity of the heart lead during subsequent tissue separation from the insulating material. In those instances where the stylet wire has not been fully inserted to the distal end of the lead, the tie also prevents the coiled structure from unravelling, breaking or separating from electrode 220 or the rest of the lead.

As previously suggested, the looped proximal end of the stylet wire can be compressed to permit separator tube 212 to be inserted thereover and over the insulating material of the heart lead. Separator tube 212 comprises a semi-rigid material, such as a TEFLON material, for sliding easily through the blood vessel and over the insulating material of the heart lead. In order to place the separator tube over the stylet, the stylet should extend at least 12 inches beyond the person's body so that the looped end can be grasped to apply tension to the stylet. With the separator tube 10 to 12 inches long, the stylet is typically three feet long.

Depicted in FIG. 4 is fibrotic tissue 209 encapsulating heart lead 204 in blood vessel 216. When this occurs in small diameter veins where blood flow has been restricted or prevented, separation and removal of the lead from the tissue is difficult and often causes severe damage or destruction to the vein. Without tension on stylet wire 200, separation is usually not possible in these situations.

As shown, the distal end of the separator tube 212 is beveled and includes a cutting edge or edge having a number of teeth for separating heart lead insulating material 201 from encapsulating fibrotic tissue 209. As depicted in FIG. 7, hollow separator tube 212 has a metal beveled tip 242 attached to the distal end thereof with, for example, a medical grade adhesive. The metal tip provides a more durable edge for separating or cutting encapsulating fibrotic tissue from the lead.

Returning the reader's attention again to FIG. 3, separator tube 212 is moved and rotated along the outer surface of insulating material 201 of the heart lead to separate the lead from the blood vessel wall. After the separator tube has been moved along the entire length of the heart lead, it will abut next to the heart cavity wall as shown by phantom lines 219. The distal end of the heart lead is typically secured to the heart cavity wall by trabeculae or fibrotic tissue 218 that has encapsulated tines 207 positioned at the distal end of the lead. The separator tube 212 is positioned next to the heart cavity wall or pushed slightly while the stylet wire is tensioned in the opposite direction. The separator tube is then rotated back and forth to dislodge and separate tines 207 and the distal end of the heart lead from fibrotic tissue 218 and heart cavity wall 213. As a result, the heart lead has now been completely separated from the blood vessel and the heart cavity wall for subsequent removal. The separator tube, the stylet wire, and the heart lead are then removed from the heart cavity and surrounding blood vessel.

However, should the removal of the heart lead be prevented for whatever reason, the stylet wire is rotated in a clockwise direction to unsecure the stylet and wire coil from the heart lead coiled structure. The time for this operation is lessened by attaching a rotating mechanism such as an electrical screwdriver to the proximal end of the stylet wire.

Depicted in FIG. 27 is an alternative embodiment of illustrative separator apparatus 2700. This separator apparatus includes a set of separator and dilator tubes 2701 and 2702 for insertion over pacemaker lead 204. Similar to separator tube 212, separator tube 2701 has a hollow passageway therein for receiving the pacemaker lead. The separator tube is advanced along the lead to engage and separate encapsulating tissue from the lead. Dilator tube 2702 similarly has a hollow passageway therein for receiving separator tube 2701 and the pacemaker lead therein. A preferred material for separator and dilator tubes 2701 and 2702 is polypropylene which is more kink-resistant than TEFLON material. A polypropylene tube fits easily into the blood vessel for extension to the distal end of the pacemaker lead. Furthermore, the inclusion of approximately 25% of bismuth provides radio-opacity for viewing with, for example, a fluoroscope during insertion of the separator tube. When the dilator tube is inserted over the separator tube and lead, a control mechanism 2703 having a hollow passageway therein is inserted over the lead and connected to the proximal end of separator tube 2101. Control mechanism is well-known as a pinvise and is used for controlling the movement of the separator tube in both a longitudinal and rotational direction. The dilator tube and separator tube are alternatively moved along the lead to first separate the tissue from the lead and further dilute the tissue with the dilator tube. The control mechanism 2103 provides added strength and control during the movement of the separator tube. Dilator tube 2102 not only provides extra dilation of the tissue but also provides additional strength to the entire structure for separating tissue from the pacemaker lead.

Depicted in FIG. 22 is another alternative embodiment of illustrative separator apparatus 2201 for separating encapsulating tissue 2205 from pacemaker lead 204. The separator apparatus 2201 includes a tube 2202 having a longitudinal passageway 2203 therein for receiving and passing over the pacemaker lead including outer insulating material 201. Distal end 2204 of the tube is beveled to provide a wedge for separating encapsulating tissue 2205 from the pacemaker lead. Also positioned and attached in a well-known manner about the distal end of the separator tube is balloon 2206. The tube also includes a plurality of hollow passageways 2207 for supplying a compressed gas or fluid for inflating the balloon. Separator apparatus is inserted over the insulating material sheath of the pacemaker lead to engage encapsulating tissue 2205. The beveled distal end provides a wedge for causing an initial separation of the tissue from the lead. Upon initial contact and separation, the balloon is inflated to provide further dilation and separation of the encapsulating tissue from the pacemaker lead. The balloon is then deflated to permit the beveled distal end to be further moved along the pacemaker lead and engage additional encapsulating tissue. This process is continued until all of the encapsulating tissue is separated from the pacemaker lead.

Depicted in FIGS. 24 and 25 is separator apparatus 2401 for separating the distal end of an elongated structure such as electrode tip 220 of pacemaker lead 204 from tissue 218 affixed thereto. This apparatus is particularly advantageous in those instances where the electrode of the pacemaker lead is porous allowing fibrotic tissue to grow therein and secure the electrode tip thereto. Separator apparatus includes a first tube 2402 having a hollow passageway 2403 for receiving pacemaker lead 204 and extending to the distal end thereof. Attached to the distal end of the first tube 2402 is an elongated member such as stainless steel wire 2404. The first tube wall also have a hollow channel or passageway 2408 extending longitudinally therethrough for passing the wire the entire length of the tube. Alternatively, the stainless steel wire can be affixed to the distal end using any suitable well-known fastening means. A second tube 2405 also has a longitudinal passageway 2406 for receiving the first tube. In addition, the second tube similarly includes a hollow channel or passageway 2407 for extending stainless steel wire 2404 through the entire length of the tube and beyond the proximal end thereof. This permits the loose end of the wire to be controlled by the clinician to remove the distal end of the pacemaker lead from the encapsulating or affixed tissue. As shown in FIG. 25, the first tube is extended to the distal end of the pacemaker lead and placed next to electrode 220. The second tube with the stainless steel wire is then also positioned next to the distal end of the pacemaker lead next to the electrode. The clinician puts tension on the stainless steel cutting wire and then rotates the second tube relative to the first causing the stainless steel wire to wipe across the face of the electrode as shown. Rotation of the two tubes are shown by arrows 2501 and 2502. This wiping motion across the pacemaker electrode literally cuts the electrode tip free from the encapsulating or affixed tissue 218. Instead of stainless steel wire, suture material is also used to perform the cutting action.

Depicted in FIG. 26 is a second alternative embodiment of illustrative separator apparatus 2601 for separating the distal end of a pacemaker lead having a plurality of tines such as tines 207 of pacemaker lead 204 encapsulated in fibrotic heart tissue 218. Apparatus 2601 includes tube 2602 having a longitudinal passageway 2605 for receiving pacemaker lead 204. The tube is inserted over the lead and extended to the distal end thereof. The tube includes a plurality of slots 2603 formed at the distal end for receiving pacemaker lead tines 207. When the tines are received in the slots, tube 2602 is rotated back and forth in a circular motion for dislodging and separating the tines from the encapsulating tissue 218 extending from heart wall tissue 213.

Depicted in FIG. 7 is another illustrative embodiment of the lead removal apparatus of this invention. In this embodiment, pacemaker lead 243 is similar to the lead shown in FIG. 3; however, the distal end of the lead is of a different configuration. In particular, electrode 244 has two cavities therein. One cavity is for receiving the coiled structure 245 of the lead. The second cavity is for receiving and securing anchoring coil 246 secured in the cavity with insulating material 247 in a well-known manner. The distal end of anchoring coil 246 is cut to form a beveled or sharpened edge for turning or corkscrewing the coil into heart cavity wall 213. Anchoring coil 246, as a result, securely attaches electrode 244 to the heart tissue to establish good electrical contact for stimulating the heart tissue with electrical pacing pulses from the pacemaker. Insulating material 248 surrounds coiled structure 245 and partially surrounds electrode 244. Since anchoring coil 246 is utilized in this configuration, the insulating material is molded over the coiled structure and electrode without forming tines for the endothelial tissue to form therearound.

Stylet wire 249 of this lead removal apparatus and lock wire 250 attached to the distal end thereof have a combined diameter much less than the inside diameter of coil structure 245 of the lead. This is particularly advantageous for those situations when the coiled structure of the lead has been deformed, unraveled, or in some way damaged. In this embodiment, lock wire 250 has a plurality of turns 251 wrapped around the distal end of the stylet wire. Turns 251 of the lock wire at the distal end of the stylet wire are closely wrapped and attached to the distal end of the stylet wire using, for example, a silver solder. Turns 252 of the lock wire are more loosely wrapped and are approximately 75 in number. The unwrapped proximal end 253 of the lock wire extends beyond the passageway of the lead and is secured and positioned by, for example, the physician's hand 258 when the stylet wire is rotated to expand lock wire turns 252 and engage the turns of coiled structure 245.

Control mechanism 254 such as a loop of malleable wire is wrapped around and secured to the proximal end of the stylet wire using, for example, silver solder 257. Slidable chuck 240 is also suitable for use as the control mechanism for stylet wire 249. A TEFLON material coating 255 surrounds the interconnection to prevent possible injury to the physician or patient. Control loop 254 is provided for the physician to move the stylet wire in and out of the passageway of the lead as well as rotate the stylet wire to engage the coiled structure of the lead. When the stylet wire is secured to the pacemaker lead, loop 254 is used to extract stylet wire and pacemaker lead from the patient.

To unravel the turns of the lock wire, a tool such as an electrical screwdriver is attached to the control mechanism loop to rotate the stylet wire and expand the turns of the lock wire. While the stylet wire is being rotated, the physician secures the position of the proximal end 253 of the lock wire to permit lock wire turns 252 to tangle and form a bundle 259 that engages the coiled structure as depicted in FIG. 8. The stylet may have to rotate 50 to 100 turns to form bundle 259 and engage coiled structure 245.

After the lock wire has secured the stylet wire to the pacemaker lead, the physician grasps control loop 254 and continues to rotate the stylet wire and pacemaker lead to dislodge anchoring coil 246 from the heart tissue. Should the blood vessels encapsulate the pacemaker lead, separator tube 212 is inserted over the stylet wire and pacemaker lead as previously described to separate the lead from the encapsulating blood vessel tissue. The separator tube may also be extended to the distal end of the pacemaker lead to turn and dislodge the distal end of the pacemaker lead from the heart tissue.

Of course, it will be understood that the aforementioned lead removal apparatus and method is merely illustrative of the application of the principles of this invention and that numerous other arrangements may be devised by those skilled in the art without departing from the spirit and scope of the invention. In particular, a number of other control mechanisms may be attached to the proximal end of the stylet wire for operating the stylet wire in either a clockwise or counterclockwise direction as well as moving the wire longitudinally. Furthermore, this apparatus may be utilized for removing electrical leads from body ducts and passages as well as body tissue that has encapsulated the lead and restricted its movement. 

What is claimed is:
 1. Apparatus for removing a pacemaker lead implanted in a heart, comprising:stylet means insertable into a longitudinal passageway of said implanted lead for controlling movement of said lead; coil means having a distal end attached about a distal end of said stylet means and operable for securing said distal end of said stylet means to said lead when said stylet means is inserted in said passageway; and catch means attached to and extending from a proximal end of said coil means and having a segment folded back thereon for engaging said lead when said coil means is operated.
 2. The apparatus of claim 1 wherein said catch means comprises a catch wire is approximately one-quarter of an inch in length.
 3. The apparatus of claim 2 wherein said folded-back segment of said catch wire is approximately one-sixteenth of an inch in length.
 4. The apparatus of claim 1 further comprising means for attaching said folded-back segment of said catch wire onto itself.
 5. The apparatus of claim 4 wherein said means for attaching comprises silver solder.
 6. Apparatus for removing an elongated coiled structure implanted in biological tissue, comprising:stylet means insertable into a longitudinal passageway of said elongated coiled structure for controlling movement of said structure; and coil means attached at a distal end thereof to a distal end of said stylet means and expandable for securing said stylet means to said structure, catch means extending from a proximal end of said wire coil and having a segment folded back thereon for engaging said elongated coiled structure and for expanding said coil means.
 7. The apparatus of claim 6 wherein said catch means comprises a catch wire is approximately one-quarter of an inch in length.
 8. The apparatus of claim 7 wherein said folded-back segment of said catch wire is approximately one-sixteenth of an inch in length.
 9. Apparatus for removing a pacemaker lead implanted in a heart, comprising:a stylet wire insertable into a longitudinal passageway formed by a coiled structure of said lead to control movement of said lead; a wire coil having a plurality of first turns wrapped around and attached at a distal end of said stylet wire and also having a plurality of second turns more open-spaced than said first turns positioned around said stylet wire and operable when inserted in said passageway to expand and engage said coiled structure; a catch wire extending approximately one-quarter of an inch from a proximal end of said wire coil and having a segment approximately one-sixteenth of an inch in length and folded back thereon to engage said coiled structure when said wire coil is operated; and silver solder for attaching said folded-back segment to said catch wire.
 10. The apparatus of claim 9 further comprising a control mechanism connected to a proximal end of said stylet wire to expand said wire coil. 